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Activity of the Russian Desman Desmana Moschata (Talpidae, Insectivora) in Its Burrow

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Activity of the Russian Desman Desmana Moschata (Talpidae, Insectivora) in Its Burrow THERYA, 2020, Vol. 11 (2): 161-167 DOI: 10.12933/therya-20-801 ISSN 2007-3364 Activity of the Russian desman Desmana moschata (Talpidae, Insectivora) in its burrow ALEXEY ANDREYCHEV1*, VYACHESLAV KUZNETSOV1, ALEXANDR LAPSHIN1 AND MAKSIM ALPEEV1 1Department of Zoology, National Research Mordovia State University, Saransk, 430000 Russia. E-mail: andreychev1@rambler. ru (AA), [email protected] (VK), [email protected] (AL), and [email protected] (MA). * Corresponding author A new method of studying for activity of a semi-aquatic mammal Russian desman Desmana moschata (Linnaeus, 1758) with use of digital portable voice recorders is developed. To identify the burrows in which the recorders were to be installed, the burrows were probed. A probe is a pole pointed at one end with a T-shaped handle at the other end. The researcher’s task was to detect the entrance to the burrow, usually under water. The direction of the underground passage is determined by means of the probe. For this purpose, the ground is pierced to detect the hollows in the burrow with the probe starting from the burrow entrance (the probe falls through unevenly). At a distance of 2 to 3 meters from the burrow, in some cases largely depending on the burrow length, the ground is dug up above the burrow in the form of a small well, 10 to 15 cm in diameter. A digital voice recorder was placed vertically in this well, so that the microphone was directed down towards the burrow. Desman noises can be characterized as short series formed as a sequence of contiguous short peaks of 15 to 25 seconds with five second inter- ruptions formed by regular waves of breathing and its movement noises. As a rule, the noise audibility ranges from 1 to 3 minutes. Se desarrolla un nuevo método de estudio para la actividad del Desman ruso Desmana moschata, mamífero semiacuático, por me- dio del uso de grabadoras portátiles digitales. Para identificar las madrigueras en las que se iban a instalar las grabadoras, se sondearon las madrigueras. Se utilizó una sonda, adjunta en un extremo a un poste con un mango en forma de T en el otro extremo. La tarea del investigador era detectar la entrada a la madriguera, generalmente bajo el agua. La dirección del tunel subterráneo se determina por medio de la sonda. Para este propósito, se perfora en el suelo huecos en la madriguera con la sonda, comenzando desde la entrada de la madriguera (la sonda cae de manera desigual). A una distancia de dos a tres metros de la madriguera, en algunos casos dependiendo en gran medida de la longitud de la madriguera, el suelo se excava sobre la madriguera en forma de un pequeño pozo, de 10 a 15 cm de diámetro. Se colocó una grabadora de voz digital verticalmente en este pozo, de modo que el micrófono se dirigió hacia la madriguera. Los ruidos de Desman se pueden caracterizar como series cortas formadas como una secuencia de picos cortos contiguos de 15 a 25 segundos con interrupciones de cinco segundos, formadas por ondas regulares de respiración y los ruidos del movimiento. Como regla general, la audibilidad del ruido varía de uno a tres minutos. Keywords: burrow; daily activity; day-night activity; desman; voice recorder. © 2020 Asociación Mexicana de Mastozoología, www.mastozoologiamexicana.org Introduction row is inhabited or uninhabited in the ice-free period. The The study of the Russian desman in the Republic of Mor- method for identifying the activity of underground excava- dovia was initiated by well-known mammalogist Boro- tion is taken as the basis (Andreychev and Zhalilov 2017; din (1963, 1970). In his monograph and articles (Borodin Andreychev 2018, 2019a). The method could be adapted 1963, 1970), stated the following habitat areas of the des- and improved for other semi-aquatic mammals (e. g. musk- man within the territory of Mordovia: Zubovo-Polyansky, rat or beaver; Andreychev 2019). Temnikovsky, Tengushevsky, Kochkurovsky, Bolsheber- The sudy of the day-night rhythm of the Russian des- eznikovsky, and Dubensky Districts. He noted that the man in the wild was carried out in the Khopersky Nature desman was found in the Sura, Moksha, Vad, Vysha, Yuzga, Reserve on Lake Kresty using an actograph. Serdyuk (1969) Partsa Rivers and their tributaries. the device was installed in inhabited and fodder burrows Our research on the desman in Mordovia has been from 2:00 pm on October 31 to 2:00 pm on November 2. intensified since 2009 until 2018. We aimed at identifying The device recorded the entry of animals into the burrows. the current distribution of the species within the region By the number of into or exits of desman from the burrow, and their populations status. In the course of expedition- their activity was determined. Two peaks of the desmans’ ary work on accounting for desmans in remote areas, we day-night activity were identified. They are associated with had the idea of checking whether the desman’s burrow is the periods of sunrise and sunset (Serdyuk 1969). Similar residential or non-residential. On the first (transparent) ice, results using a night vision device were obtained in Ryazan finding out whether a burrow is inhabited or uninhabited is region in July 1967 (Khakhin and Ivanov 1990). not difficult. However, clear ice is not always; moreover, it In the Seltsov hunting estate, Vladimir region, the num- is problematic to have time to examine a large number of ber of burrow entries was recorded by an actograph for 51 reservoirs in the short-term period of clear ice. Therefore, days from November 1972 to April 1973. Three seasonal we have developed a technique that allows studying the periods of desmans’ activity associated with changes in desman’s activity in a hole and determining whether a bur- external conditions were identified. The first period is asso- ACTIVITY OF THE RUSSIAN DESMAN ciated with the beginning of freeze-up (November–Decem- –55º 11’ 41’’ N and 42º 11’ 53’’, –46º 45’ 16’’ E. Features of ber) and it is characterized by high activity. The second the geological structure of Mordovia are determined by its period is associated with strong freeze-up (January–Febru- location in the central part of the Russian Platform and the ary). The activity of animals decreases during this period. north-western slopes of the Volga Upland. In the western They spend most of their time in burrows. The third period part of the Republic of Mordovia, the Volga Upland reaches is associated with the end of freeze-up (end of March – the Oka-Don Lowlands. beginning of April). It is characterized by increased activ- The climate of the region is moderate with pronounced ity, but less than during the freeze-up period (Khakhin and seasons throughout the year. The influx of direct solar radia- Ivanov 1990). There are three peaks of day-night activity tion in Mordovia varies from 5.0 in December to 58.6 kJ / cm2 during freeze-up: morning (5:30 to 7:30), afternoon (12:30 in June. Total radiation throughout the year is 363.8 kJ / cm2; to 14:30), and evening (19:30 to 21:30; Barabash-Nikiforov the radiation balance is 92.1 kJ / cm2. The average annual et al. 1964; Sokolov et al. 1984; Sukhov 1984); in some cases, air temperature varies from 3.5 to 4.0 °C. The average tem- the fourth peak is recorded (23.00 to 0:00; Khakhin and Iva- perature of the coldest month (January) is in the range of nov 1990). –11.5 to –12.3 °C. Temperature drops down to –47 °C occur. With the use of actographs and a night vision device, The average temperature of the warmest month, i.e. July, only activity at the entry to the burrow was recorded. With is in the range of 18.9 to 19.8 °C. Extreme temperatures in regard to identifying the burrow activity of semiaquatic the summer reach 37 °C. The average annual precipitation inhabitants, in particular, the Russian desman, both of the in the territory of Mordovia is 480 mm. Over the course of above methods are largely unsuitable. Since the animal can observation lasting many years, periods of more and less use another entrance or be active inside the burrow. humidification were noted, ranging between the minimum Detailed studies of the daily and seasonal activity of and maximum values of 120 to 180 mm. Distribution of pre- the Russian desman have been conducted by Onufrenya cipitation across the territory is not very diverse. The aver- and Onufrenya (2016). They noted that the duration of the age long-term value of evaporation is calculated to be in the continuous stay of the desman in water, regardless of the range of 390 to 460 mm (Yamashkin 1998). season of the year, rarely exceeds four to five minutes. The Surveys were carried out on the possible habitats of maximum values of this indicator, noted in different indi- the Russian desman in areas of the Republic of Mordovia viduals for all the time of observation, lie within 18.8 to 65.7 in order to find its holes for subsequent study of activity min (Onufrenya and Onufrenya 2016). A detailed discussion (Figure 1). In the course of the field work, we used burrows of their results is given below in comparison with our data. to a greater extent, which are known to us from of expedi- The majority of researches on activity of the Russian des- tionary work of 2009 to 2012 in the Tengushevsky region mans have been conducted in experimental captive con- (Andreychev et al. 2012). As a result, we also found desman ditions (Barabash-Nikiforov et al.
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